JP4975868B2 - Apparatus and method for generating and analyzing MACPDU in mobile communication system - Google Patents

Description

  The present invention relates to a mobile communication system, and more particularly, to an apparatus and method for generating and analyzing a medium access control (MAC) header using optimized information.

Mobile communication systems have evolved into high-speed, high-quality wireless data packet communication systems for providing data services and multimedia services as well as conventional voice services. 3rd generation using Wideband Code Division Multiple Access (hereinafter referred to as “CDMA”) based on European system GSM (Global System for Mobile Communications) and GPRS (General Packet Radio Services) (3G) UMTS (Universal Mobile Telecommunication Service) system, which is a mobile communication system, enables mobile phones and computer users to transmit packet-based text, digitized audio or video data, and multimedia data at 2 Mbps or higher anywhere in the world. Provide consistent services that can be transmitted at high speed. The UMTS system can be connected to any terminal in the network by a packet switching connection concept using a packet protocol such as the Internet Protocol (IP).
The 3rd Generation Partnership Project (3GPP) responsible for standardization of the UMTS system is under discussion for LTE (Long Term Evolution) as the next generation UMTS mobile communication system. LTE aims at realizing high-speed packet communication of about 100 Mbps, and various methods are being discussed for this purpose. For example, there is a technique for reducing the number of nodes on a communication path by simplifying the network structure or optimizing a radio protocol for a radio channel.

FIG. 1 shows a function of a MAC layer of a conventional LTE mobile communication system.
Referring to FIG. 1, at a transmitter, first and second radio link control (hereinafter referred to as “RLC”) entities 102 and 104 receive RLC SDUs (Service Data Units) received from an upper layer. ) Are each composed of one RLC PDU (Protocol Data Unit). The MAC layer 106 transmits the RLC PDU to the receiver via the physical (PHY) layer 108. At the receiver, the MAC layer 112 receives RLC PDUs via the PHY layer 110 and provides them to the associated RLC entities 114, 116. These RLC entities 114 and 116 extract the RLC SDU and provide it to the upper layer.
The RLC PDU is analyzed as a MAC SDU in the MAC layer 106. The MAC layer 106 generates a MAC header, and configures one MAC PDU by combining the MAC header and the MAC SDU. The MAC PDU may include a MAC SDU for controlling transmission and reception between the transmitter and receiver MAC layers 106 and 112 in addition to the MAC SDU received from the RLC entities 102 and 104. The MAC SDU for control may be transmitted together with the MAC SDU for data transmission in the MAC PDU, or may be transmitted alone in the MAC PDU. Therefore, the header of the MAC PDU (hereinafter referred to as “MAC header”) is configured to distinguish the MAC SDU for data transmission from the MAC SDU for control.

FIG. 2A shows a format of a MAC PDU in a conventional mobile communication system.
Referring to FIG. 2A, a MAC PDU includes a MAC header 200 and payloads 209, 210, and 211 that carry one or more MAC SDUs. The MAC header 200 includes logical channel identifier (LCID) fields 201, 204, 207, E fields 202, 205, 208, and length fields 203, 206.
The LCIDs 201, 204, and 207 distinguish MAC SDUs transmitted to various logical channels.
E202, 205, and 208 indicate whether there is another multiplexed MAC SDU, respectively. If E is 0, this means that the corresponding MAC SDU is the last MAC SDU. If E is 1, this means that the corresponding MAC SDU is followed by other multiplexed MAC SDUs. In the latter case, a length field (LF) and LCID follow the E field.
LFs 203 and 206 indicate the length of the corresponding MAC SDU. Therefore, these LFs 203 and 206 must be long enough to represent the length of the MAC SDU.

Here, the minimum unit of the related information in which the MAC header is multiplexed is referred to as a “subheader”. For example, the subheader for one MAC SDU is header information including LCID, E, and LF. In some cases, a part of the subheader may be omitted, or one MAC header may include different types of subheaders. A padding header described later is treated as a subheader that carries information related to padding, even if it is not a subheader for MAC SDU.
Referring to FIG. 2A, in the MAC header 200, the first subheader 213 composed of LCID 201, E202, and LF 203 is related to the first MAC SDU 209, and the second subheader 215 composed of LCID 204, E205, and LF 206 is the first subheader 215. A third subheader 217 consisting of LCID 207 and E208 is associated with the third MAC SDU 211.
As can be seen from FIG. 2A, the third subheader 217 does not include LF. The reason is that the MAC PDU size, that is, the transport block (TB) size, is known for both the transmitter and the receiver. Therefore, the receiver determines the length of the LFs 203 and 206 and the length of the MAC header 200 from the TB size. And the size of the third MAC SDU 211 can be determined. Therefore, the LF is not necessary for the third MAC SDU 211, and instead, other user data can be transmitted to the LF space, thereby increasing transmission efficiency.

However, for accurate data transmission and reception, both the transmitter and receiver must know which MAC SDUs are not included in the LF. There are usually two possible ways to provide this information.
In the first method, the transmitter notifies the receiver of the position information of the absent LF. In the second method, the transmitter and receiver pre-promise the absence of the LF in the subheader at a specific location. In particular, LF is not present in the last subheader.
However, the absence of the LF in the last subheader causes the following problems.
In general, the MAC PDU performs padding. In the padding of the MAC PDU, padding bits (or dummy bits) are added to an empty area of the TB where the amount of transmission data is smaller than the predetermined TB size in order to match the TB to the predetermined TB size. In order to indicate this padding, a “padding subheader” is added to the header of the MAC PDU. If space remains after that, the payload is padded.

The absence of the last LF causes the following problem when the padding size is equal to or smaller than the size of the last LF. Here, the last LF means “LF for the last MAC SDU” of one or more MAC SDUs included in the MAC PDU.
When the TB size is set to 100 bytes and the last LF is 2 bytes, the absence of the last LF generates a 2-byte free area in the TB that allows additional data transmission. When 1 byte of data is added, the required padding is 1 byte. If there is no additional data to be transmitted, the required padding is 2 bytes. Thus, when the padding size is less than or equal to the length of the LF, the following contradiction is encountered.
First, when the last LF is not included and 1-byte data is added, 1-byte padding is necessary. To indicate this padding, the padding subheader is no longer the last subheader because it is combined with the MAC header. Since the last LF is not "LF for the last subheader", it must be omitted. Thereafter, the last LF of 2 bytes must be included in the MAC header, but the problem arises that the size of the TB increases to 102 bytes. Therefore, a contradiction occurs in which 1-byte data to be added and 1-byte padding are to be deleted.
Second, if the last LF is not included and no data is added, the required padding is 2 bytes. Also in this case, there is a problem that the above contradiction occurs.

Accordingly, the present invention has been made in view of the above-described problems of the related art, and an object thereof is an apparatus and method for generating a MAC PDU having a MAC header optimized in a mobile communication system, and An object of the present invention is to provide an apparatus and method for receiving and parsing a generated MAC PDU.
Another object of the present invention is to provide an apparatus and method for clarifying whether the last LF is included in a MAC PDU in a mobile communication system, simplifying a MAC PDU configuration process, and increasing a data processing speed. There is.
Another object of the present invention is to not include the last LF in the MAC header in order to optimize the MAC header in the mobile communication system, but include it in the MAC header if the required padding size is less than or equal to the size of the last LF An apparatus and method for generating a MAC PDU and an apparatus and method for receiving the same are provided.

  In order to achieve the above object, according to one aspect of the present invention, there is provided a method of generating a MAC PDU in a mobile communication system, the step of confirming the LCID of a MAC SDU to be multiplexed, Determining a length of LF for each MAC SDU with reference to a predetermined length of LF, generating a MAC header including the LCID for the MAC SDU and the determined length of LF; and MAC SDU Generating a MAC PDU by combining a MAC header with a payload including the MAC PDU generation step, assuming that the last LF of the MAC header is omitted. If the required padding size is larger than the length of the last LF, include the last LF in the MAC header, The method further includes a step of recalculating a necessary padding size in consideration of inclusion of LF later and adding padding according to the recalculated padding size. If the required padding size is less than or equal to the length of the last LF, the last LF is included in the MAC header.

  According to another aspect of the present invention, an apparatus for generating a MAC PDU in a mobile communication system provides a MAC SDU to be multiplexed to a multiplexer, confirms the LCID of the MAC SDU, and determines the length of the LF for each MAC SDU. Determine the length, refer to a predetermined LF length for the LCID, determine at least one RLC entity that provides the LCID and the determined LF length to the header generator, and the LCID for the MAC SDU A header generation unit that generates a MAC header including the length of the generated LF and provides the MAC header to the multiplexer; and a multiplexer that multiplexes the MAC header with at least one MAC SDU. The padding size required for the MAC PDU is the last one assuming that the LF is absent. If the length is larger than the LF length, the last LF is included in the MAC header, the necessary padding size is recalculated in consideration of the inclusion of the last LF, padding is added according to the recalculated padding size, and the last is added to the MAC header. LFs are included. If the required padding size is less than or equal to the length of the last LF, the header generation unit includes the last LF in the MAC header.

  According to another aspect of the present invention, there is provided a method for parsing a MAC SDU from a MAC PDU in a mobile communication system, wherein the LCID of a MAC SDU multiplexed on a MAC PDU received from a MAC PDU of the MAC PDU is obtained. A step of checking, a step of determining whether the length of the MAC PDU calculated using the MAC header is the same as a known TB size, and the last LF associated with the last MAC SDU in the MAC header Determining that the MAC PDU is parsed from the MAC PDU by the LF in the MAC header, and determining that the last LF is not included in the MAC header if the length of the MAC PDU is different from the TB size; Persist MAC SDU from MAC PDU by absent last LF and LF in MAC header And a step of immediately.

  Further, according to another aspect of the present invention, an apparatus for parsing a MAC SDU with a MAC PDU in a mobile communication system, wherein the LCID of the MAC SDU multiplexed into the MAC PDU is received from the MAC header of the received MAC PDU. And includes a header detector that provides the SDU detector with the size of the MAC SDU multiplexed with a predetermined LF length for the LCID, the SDU detector including the LCID and MAC SDU size If the calculated MAC PDU length is the same as the known TB size, it is determined that the last LF associated with the last MAC SDU is included in the MAC header, and the MAC header LF determines the MAC PDU from the MAC PDU to the MAC PDU. If the SDU is parsed and the length of the MAC PDU is not the same as the TB size, the last LF Determined not to be included in the header and parses the MAC SDU from MAC PDU by the absence of the last LF and MAC header LF.

  According to another aspect of the present invention, there is provided a method for generating a MAC PDU in a mobile communication system, the step of confirming the LCID of a MAC SDU to be multiplexed, and a length of an LF predetermined for the LCID Determining the length of the LF for each MAC SDU, generating a MAC header including the LCID for the MAC SDU and the determined length of LF, and combining the MAC header with a payload including the MAC SDU Generating a MAC PDU. The step of generating the MAC header includes including the last LF and the length indicator in the MAC header and the E field as the last LF if the required padding size is less than or equal to the sum of the length of the last LF and the length indicator. The method further includes the step of setting to a value indicating inclusion of the length indicator and setting to a predetermined value indicating that the subheader including the last LF is the last subheader.

  Furthermore, according to another aspect of the present invention, a MAC PDU generation apparatus in a mobile communication system provides a MAC SDU to be multiplexed to a multiplexer, confirms the LCID of the MAC SDU, and performs LF for each MAC SDU. The at least one RLC entity that provides the header generation unit with the LCID and the determined LF length, and the LCID for the MAC SDU. A header generation unit that generates a MAC header including the LF having the specified length and provides the MAC header to the multiplexer; and a multiplexer that multiplexes the MAC header with at least one MAC SDU. When the required padding size is equal to or less than the sum of the length of the last LF and the length indicator, the header generation unit includes the last LF and the length indicator in the MAC header and includes the E field as the last LF and the length indicator. And a predetermined value indicating that the subheader including the last LF is the last subheader.

  Furthermore, according to another aspect of the present invention, there is provided a method for parsing a MAC SDU with a MAC PDU in a mobile communication system, wherein the LCID of the MAC SDU multiplexed in the MAC PDU from the MAC header of the received MAC PDU. And confirming the E field of the MAC header, and if the E field is set to a predetermined value indicating the absence of the last LF associated with the last MAC SDU and the absence of the length indicator for the last LF, Calculating the length of the last MAC SDU taking into account the last LF and length indicator, and parsing the MAC SDU from the MAC PDU using the LCID and the length of the last MAC SDU. .

  In addition, according to another aspect of the present invention, an apparatus for parsing a MAC SDU with a MAC PDU in a mobile communication system, the MAC SDU multiplexed in the MAC PDU from a MAC header of the received MAC PDU. A header detector that checks the LCID and checks the E field of the MAC header, and when the E field is set to a predetermined value indicating the absence of the LF associated with the last MAC SDU and the length indicator for the last LF; Calculates the length of the last MAC SDU taking into account the missing last LF and length indicator, and includes an SDU detector that parses the MAC SDU from the MAC PDU using the LCID and the length of the last MAC SDU .

  The present invention solves the problems related to the generation and optimization of the MAC header by including the last LF when the padding size required for generating the MAC PDU is less than or equal to the length of the last LF. Has an effect. In addition, there is an effect of increasing the data communication speed by reducing the MAC PDU generation time.

It is a figure which shows the function of the MAC layer in the conventional LTE mobile communication system. It is a figure which shows the format of MAC PDU in the conventional mobile communication system. FIG. 4 is a diagram illustrating a format of a MAC header according to an embodiment of the present invention. It is a block block diagram which shows the MAC PDU generation part of the transmitter in the mobile communication system by embodiment of this invention. FIG. 3 is a block diagram illustrating a MAC PDU receiver of a receiver in a mobile communication system according to an embodiment of the present invention. 5 is a flowchart illustrating an operation of generating a MAC PDU having a MAC header in a transmitter of a mobile communication system according to an embodiment of the present invention. 5 is a flowchart illustrating an operation of generating a MAC PDU having a MAC header in a transmitter of a mobile communication system according to an embodiment of the present invention. 5 is a flowchart illustrating an operation of generating a MAC PDU having a MAC header in a transmitter of a mobile communication system according to an embodiment of the present invention. 5 is a flowchart illustrating an operation of generating a MAC PDU having a MAC header in a transmitter of a mobile communication system according to an embodiment of the present invention. 5 is a flowchart illustrating an operation of generating a MAC PDU having a MAC header in a transmitter of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. 6 is a flowchart illustrating an operation of detecting a MAC header and a MAC SDU from a MAC PDU in a receiver of a mobile communication system according to an embodiment of the present invention. FIG. 3 is a diagram illustrating a format of a MAC PDU according to an embodiment of the present invention. 3 is a flowchart illustrating a transmission operation according to an embodiment of the present invention. 4 is a flowchart illustrating a reception operation according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.
In the attached figures, identical or functionally similar elements are given the same reference numerals and reference numerals. Reference numerals are used in the detailed description to indicate various embodiments and various aspects and advantages of the present invention.
The embodiments of the present invention are defined based on the claims and their equivalents, and include various detailed descriptions to facilitate understanding. However, these detailed descriptions are merely considered as typical examples. Accordingly, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention described below without departing from the scope or spirit of the invention. Note that specific descriptions of known functions or configurations are omitted for clarity and conciseness.
Although embodiments of the present invention are described in the context of a 3GPP LTE system based on UMTS, the structure of the MAC header is within the scope of the present invention for other mobile communication systems with similar technical background and channel structure. It can be applied with minor modifications, which will be apparent to those skilled in the art of the present invention.
In the following, the invention will be described with reference to two embodiments. The first and second embodiments will be described with reference to FIGS. 2 to 6 and FIGS. 7 to 9, respectively.

<First Embodiment>
Prior to detailed description of the first embodiment of the present invention, first, the main concept of this embodiment will be described. The construction of the MAC PDU goes through two major steps. One step is a step of arranging MAC SDUs (SDU ordering), and the other step is a step of generating MAC PDUs by the arranged MAC SDUs (PDU generation).
It should be noted that in the embodiment of the present invention, the padding size is compared with the length of the last LF only when the padding size is larger than 0, that is, when padding is present. In other words, this embodiment does not consider the case where there is no padding in the MAC PDU.
For optimization of the MAC header according to the embodiment of the present invention, all the LF and other fields related to LF can be omitted. Accordingly, only the omission of LF will be described below, but the present invention is not limited thereto, and it is needless to say that other fields related to LF can be omitted.

SDU sequencing is described with reference to three embodiments of the present invention that illustrate the LF length determination scheme. In the first embodiment, the same LF length is set for each logical channel. In the second embodiment, different LF lengths are set for different logical channels. In the third embodiment, the LF length is “TB size”. Is set to "minimum value required to represent".
PDU generation depends on whether the required padding size is less than or equal to the length of the last LF. That is, the MAC PDU is configured in a different manner depending on whether the padding size exceeds the length of the last LF or does not exceed the above length.
When the required padding size exceeds the last LF, it is recalculated taking into account the inclusion of the last LF, and the MAC PDU is padded with the recalculated padding size and generated to include the last LF.
On the other hand, if the required padding size is less than or equal to the length of the last LF, one of two embodiments can be considered to solve the situation.
According to one embodiment of PDU generation, the MAC PDU is configured to include the last LF. In this embodiment, there are specifically five cases, which will be described later. According to another embodiment of PDU generation, the MAC PDU is configured without a final LF. In particular, the MAC PDU is padded without the last LF and sets the Reserve (R) field (or a specific indicator) to a predetermined value. The use of this R field is defined to indicate that the “MAC PDU padded without the last LF” and the padding size is represented by the value of the R field.

Hereinafter, embodiments of the SDU arrangement according to the present invention will be described in detail.
In the first embodiment of SDU arrangement, a fixed LF length is set and MAC SDUs are arranged. Since each logical channel has the same LF length, MAC SDUs can be arranged without any special conditions. For example, SDUs are randomly arranged.
In the second embodiment of the SDU array, the LF length is based on the logical channel. The amount of data varies depending on the logical channel for transmitting data in the mobile communication system. The amount of data transmitted to the logical channel is based on the characteristics of the logical channel, and different LF lengths are set for different logical channels in the configuration of the MAC header. From the side of the MAC header, the LF length varies depending on the LCID.
Thereafter, the subheader with the longest LF and the MAC SDU described by this subheader are placed at the end of the MAC header and the last payload, respectively. When the MAC PDU is configured without the last LF, the absence of the longest LF increases the transmission efficiency, thereby optimizing the configuration of the MAC PDU.
The third embodiment of the SDU array is characterized by an LF length based on the TB size set to “minimum value required to represent the TB size”. By preventing unnecessary resource consumption, the MAC header can be efficiently configured.
The arrangement of the MAC SDU is performed by generating a PDU described later.

To determine whether a MAC PDU has been padded, the padding size required to generate the MAC PDU is calculated assuming the absence of LF (ie, the last LF) for the last subheader arranged. The calculated padding size is then compared with the length of the last LF.
The comparison result will be described in two parts. One is when the padding size exceeds the last LF, and the other is when the padding size is less than or equal to the length of the last LF.
In the first result, if TB is 100 bytes, the sum of the lengths of the arranged MAC SDUs and the subheader is 99 bytes, and the last LF is 1 byte, the sum of the length is calculated by the absence of this last LF. Is 98 bytes. If there is no other data to be additionally transmitted at the position of the last LF, 2 bytes are a free area, so the required padding size is 2 bytes. Therefore, the required padding size (2 bytes) exceeds the length of the last LF (1 byte).
In this case, the necessary padding size is recalculated considering the inclusion of the last LF, and the MAC header is generated so as to include the padding header according to the recalculated padding size.
In the above example, the sum of the length of the SDU including the last LF and the subheader is 99 bytes. Thereafter, the recalculated padding size is 1 byte. Finally, the required padding size is determined to be 1 byte, and the MAC PDU is configured to include a MAC header having a padding header according to the final padding size.
For the second case where the required padding size is less than or equal to the length of the last LF, the TB is 100 bytes, the size of the transmission data including the MAC header and payload is 100 bytes, and the last LF is 2 bytes. Yes, if the data transferred to the position of the last LF is 1 byte, the required padding size is 1 byte when it is assumed that there is no last LF. That is, the required padding size is less than or equal to the length of the last LF.

As described above, the first and second embodiments of PDU generation can be used in the above case. The choice between them is based on the system implementation.
The first embodiment of PDU generation is characterized in that the MAC PDU is configured to include the last LF without padding. In the above example, since the MAC PDU includes the last LF, the MAC PDU includes a 100-byte MAC header and a payload. The five specific cases for MAC PDU generation are described in more detail with reference to FIG. 5D.
On the other hand, the MAC PDU is generated by padding without the last LF. Here, it should be noted that the last LF-free padding is represented at the receiver by setting the R field to a predetermined value in order to resolve the conflict encountered by the prior art. For reference, the R field is a field defined as one of the MAC headers in the 3GPP standard, but its use has not yet been specified. In other embodiments, instead of the R field, a specific indicator can be inserted into the MAC header for the same purpose.
For example, if the last LF is 2 bytes and 1 byte data is added, the absence of the last LF and the addition of 1 byte data will result in a 1 byte space. This 1-byte space is filled with a padding subheader. In this case, the R field of the existing last subheader before the padding subheader is set to an appropriate value representing the entire padding size including the length of the padding subheader.

In an embodiment of the present invention, the R field is defined to indicate that “MAC PDU is combined with the padding header without the last LF”, and the number of bits of this R field can indicate the padding size. This is possible because the padding size is less than or equal to the length of the last LF. As an example, the padding size can be displayed using 2 bits of a 1-byte R field.
FIG. 2B shows a structure of a MAC header having an R field according to an embodiment of the present invention.
FIG. 2B shows a format of a MAC header having an R field according to an embodiment of the present invention. Referring to FIG. 2B, the MAC header includes LCID 231, E232, R233, and length (ie, LF) 234.

An apparatus according to an embodiment of the present invention will be described with reference to FIGS.
FIG. 3 is a block diagram illustrating a MAC PDU generator of a transmitter in a mobile communication system according to an embodiment of the present invention.
Referring to FIG. 3, the MAC PDU generator includes a multiplexer (MUX) 300, RLC entities 302, 304, and 306, a MAC controller 308, and a header generator 310.
The RLC entities 302, 304, and 306 transmit each MAC SDU to the MUX 300, and transmit the LCID and LF value related to the MAC SDU to the header generation unit 310.
When there is a MAC SDU that carries a control signal used for control of the MAC protocol, the MAC control unit 308 transmits the control MAC SDU to the MUX 300, and the LCID and LF value related to the control MAC SDU are generated as a header. To 310.
The length of the LF can be set in different manners according to embodiments of the present invention. More specifically, in the first embodiment, the LF has the same length, and the subheader and the MAC SDU are arranged. In the second embodiment, the LF has a different length depending on the logical channel associated with each. In the third embodiment, the LF has a minimum length required to represent the TB size.

The header generation unit 310 generates a MAC header having LCID and LF values received from the RLC entities 302, 304, and 306 and the MAC control unit 308. The header generation unit 310 provides the MAC header to the MUX 300, and controls the arrangement order of the MAC SDUs via the MUX 300.
More specifically, the header generation unit 310 can control the MUX 300 to arrange MAC SDUs according to the first embodiment of the SDU array, and the longest LF according to the second or third embodiment of the SDU array. The MUX 300 can be controlled such that the MAC SDU corresponding to is arranged in the last payload. Further, the header generation unit 310 generates a MAC header by combining the sub-headers according to the MAC SDU arrangement order, and transmits the MAC header to the MUX 300.
As described above, the generation of the MAC PDU is based on whether the padding size required for the construction of the MAC PDU is larger than the length of the last LF or less than the length of the last LF.
If the required padding size is longer than the length of the last LF, the required padding size is recalculated, and considering the inclusion of the last LF, the MAC PDU is configured with the recalculated padding size.
On the other hand, if the required padding size is less than or equal to the length of the last LF, the first or second embodiment of PDU generation described above is used.
The MUX 300 multiplexes the MAC header and the MAC SDU according to the arrangement order of the MAC SDU according to each embodiment, and provides the generated MAC PDU to the PHY layer.

FIG. 4 is a block diagram illustrating a MAC PDU receiver in a mobile communication system according to an embodiment of the present invention.
Referring to FIG. 4, the MAC PDU receiver includes a header detector 400, an SDU detector 402, an RLC entity 404, and a MAC controller 406.
The header detector 400 detects the LCID multiplexed in the received MAC PDU and the length of the MAC SDU from the MAC header of the MAC PDU. The length of the MAC SDU is known from the LF of the MAC header.
Moreover, LF is the same length in 1st Embodiment. The LF has a different length based on the associated logical channel. The longest LF subheader is located at the end of the MAC header. In the third embodiment of the present invention, LF is the minimum length required to represent the TB size.
If the received MAC PDU exceeds the length of the last LF when the required padding size calculated assuming the absence of the last LF exceeds the length of the last LF, the recalculated padding is taken into account. Including. On the other hand, if the required padding size is less than or equal to the length of the last LF, the last LF is included according to the first embodiment of PDU generation, and the padding and R fields are included without the last LF according to the second embodiment of PDU generation. including.
The SDU detector 402 extracts the MAC SDU from the MAC PDU based on the LCID received from the header detector 400 and information on the length of the MAC SDU, and the MAC SDU data is provided to the RLC entity 404 for data control. The MAC SDU is provided to the MAC control unit 406. This operation will be described later in more detail with reference to FIGS. 6A to 6H.

Hereinafter, an operation of generating a MAC PDU on the transmission side according to an embodiment of the present invention will be described.
5A to 5E are flowcharts illustrating a MAC PDU generation operation of a transmitter in a mobile communication system according to an embodiment of the present invention. In particular, FIGS. 5A, 5B, and 5C illustrate SDU array operations according to the first to third embodiments of the SDU array, respectively. 5D and 5E illustrate operations for generating a MAC header and configuring a MAC PDU, respectively, according to the first and second embodiments of PDU generation. The above operation is shown in FIGS. 5A, 5B, and 5C.

Referring to FIG. 5A illustrating the first embodiment of the SDU array, when the transmitter detects the occurrence of a MAC PDU generation event in step 501, the transmitter has a fixed LF length without any additional processing on the MAC header. The procedure proceeds to the procedure of FIG. 5D or FIG. 5E in consideration of the format of the MAC header.
Referring to FIG. 5B illustrating a second embodiment of the SDU arrangement, when the transmitter detects the occurrence of a MAC PDU generation event in step 503, in step 505, the transmitter determines the LF length for each logical channel, and finally The MAC SDU indicated by the subheader and the subheader having the longest LF at the end of the MAC header are arranged. Thereafter, the transmitter proceeds to the procedure of FIG. 5D or FIG. 5E.
Referring to FIG. 5C, which shows a third embodiment of the SDU arrangement, when the transmitter detects the occurrence of a MAC PDU generation event in step 507, it is requested in step 509 to represent the TB size for each logical channel. The minimum LF length is determined, and the MAC SDU indicated by the subheader in the last payload and the subheader having the longest LF at the end of the MAC header are arranged. Thereafter, the transmitter proceeds to the procedure of FIG. 5D or FIG. 5E.

Referring to FIG. 5D, the transmitter performs the SDU arranging operation according to the first to third embodiments, and then the padding size required for the MAC PDU configuration is equal to or less than the length of the last LF in step 511. It is determined whether or not. If the required padding size is greater than the length of the last LF, the transmitter proceeds to step 517.
In step 517, the transmitter recalculates the required padding size considering the inclusion of the last LF. Thereafter, in step 513, the transmitter configures a MAC header including a padding header according to the recalculated padding size.
On the other hand, if the padding size is less than or equal to the length of the last LF at step 511, the transmitter constructs a MAC header including the last LF according to the first embodiment of PDU generation at step 513. In step 515, the transmitter generates a MAC PDU by multiplexing with at least one MAC SDU carrying the MAC header.

The next five cases are described by the first embodiment of PDU generation.
Case 1: A MAC PDU is generated including the last LF without padding.
Case 2: When there is an extra reserved bit in the MAC header, a value indicating that the last LF is included in the extra reserved bit is set.
Case 3: The MAC PDU includes the last LF, and the E field corresponding to the last MAC SDU is set to “1” indicating inclusion of the last LF. The setting of the E field has a different meaning from the conventional E field described with reference to FIG. 2A.
Case 4: The MAC PDU includes the last LF set to a pattern indicating the inclusion of the last LF. For example, the last LF is all set to 0 to indicate the presence of the last LF.
Case 5: The MAC PDU includes the last LF set in a pattern indicating the inclusion of the last LF, and the E field corresponding to the last MAC SDU is set to '1'. Case 5 is a combination of case 3 and case 4.
In case 4 and case 5, the last LF pattern means that the last LF is all set to zero. That is, when the last LF has a length of 7 bits, it can be '0000 000', and when the last LF has a length of 15 bits, it can be '0000 0000 0000 000'. Of course, the above pattern may be set to another value by prior consent.

Referring to FIG. 5E, after the SDU array operation according to the first to third embodiments of the SDU array is performed, the transmitter determines that the padding size required to construct the MAC PDU is the last LF in step 521. It is determined whether or not the length is equal to or less than the length of. If the required padding size is greater than the last LF size, the transmitter proceeds to step 531.
In step 531, the transmitter recalculates the required padding size considering the inclusion of the last LF. The transmitter then constructs a MAC header including a padding header with the last LF and the recalculated required padding size at step 527.
On the other hand, if the padding size required in step 521 is less than or equal to the length of the last LF, the transmitter constructs a MAC header including the R field without the last LF in step 523. The R field is set to mean “the last LF is not included, but a padding header is added”, and the value indicates the padding size. In step 525, the transmitter pads the MAC PDU. The transmitter then generates a MAC header that includes a padding header without a final LF at step 527. Steps 523 to 527 are based on the second embodiment of PDU generation. In step 529, the transmitter generates a MAC PDU by multiplexing with at least one MAC SDU that transmits the MAC header.

Hereinafter, the MAC PUD reception of the receiver according to the embodiment of the present invention will be described.
Reception of the MAC PDU includes a confirmation step for determining the LF length of the header, an SDU parsing step for determining whether the last LF is included, and thereby parsing the MAC SDU. .
In the header confirmation step, the length of the LCID and LF is determined by the MAC header of the received MAC PDU. To determine the length of the LF, the receiver operates corresponding to the first to third embodiments of the SDU array of the transmitter. For convenience, operations corresponding to the first to third embodiments of the SDU array are referred to as header confirmation first to third embodiments.
The SDU parsing step corresponds to the PDU generation operation of the transmitter. The present invention proposes a fifth embodiment for determining whether the last LF is included in the SDU parsing step. This fifth embodiment is referred to as first to fifth embodiments of SDU parsing.
According to an embodiment of the present invention, in order to determine whether the last LF is included in the MAC PDU, the length of the MAC PDU is determined assuming that the last LF is included. If the length of the MAC PDU is the same as the known TB size, the receiver determines that the last LF is included. On the other hand, if the lengths are different, the receiver determines that the last LF is not included.
In particular, the second embodiment of SDU parsing corresponds to the second embodiment of PDU generation that can determine from the R field of the MAC PDU whether or not the last LF is included in the MAC PDU.

6A to 6H are flowcharts illustrating a MAC SDU detection operation of a receiver in a mobile communication system according to an embodiment of the present invention.
6A, 6B, and 6C show the operations shown in FIGS. 5A, 5B, and 5C, that is, the reception operations corresponding to the first to third embodiments of header confirmation, respectively.
FIG. 6E shows a reception operation corresponding to FIG. 5E. 6D shows a receiving operation corresponding to case 1 and case 2 shown in FIG. 5D, FIG. 6F shows a receiving operation corresponding to case 3 shown in FIG. 5D, and FIGS. 6G and 6H show cases 4 and 6 respectively. The reception operation corresponding to Case 5 is shown. The reception operations shown in FIGS. 6E to 6H are based on the first to fifth embodiments of SDU parsing.

Referring to FIG. 6A showing the first embodiment of header confirmation, the receiver receives the MAC PDU at step 601 and confirms the LCID and the fixed LF length with the MAC header of the MAC PDU at step 603. Thereafter, the procedure shown in one of FIGS. 6D to 6H is performed.
Referring to FIG. 6B showing the second embodiment of header confirmation, the receiver receives the MAC PDU in step 605, confirms the LCID in the MAC header of the MAC PDU in step 607, and determines the predetermined value by the LCID in step 609. Check the length of the LF. Thereafter, the receiver proceeds with the procedure shown in one of FIGS. 6D to 6H.
Referring to FIG. 6C showing a third embodiment of header verification, the receiver receives a MAC PDU in step 611 and in step 613, the minimum value required to represent the TB size in the MAC header of the MAC PDU. In step 615, the LCID is confirmed using the MAC header. Thereafter, the receiver proceeds with the procedure shown in one of FIGS. 6D to 6H.

Referring to FIG. 6D which shows the first embodiment of SDU parsing corresponding to case 1 and case 2 according to the first embodiment of PDU generation, the receiver has not yet confirmed with the MAC PDU at step 621. It is determined whether there is another multiplexed MAC SDU. If there is a MAC SDU, the receiver proceeds to one of the procedures shown in FIG. 6A, FIG. 6B, and FIG. 6C, as indicated by reference symbol B, and confirms the subheaders for all MAC SDUs in the MAC header. Repeat until When the sub-header verification for all MAC SDUs is completed in step 621, the receiver proceeds to step 623.
In step 623, the receiver calculates the length of the MAC SDU using all the LF values in the MAC header, assuming that the last LF is included in the MAC PDU, and sets the MAC PDU length to Based on the total size of the MAC PDU is calculated. The sum of all LF values is the sum of the length of the MAC SDU and the length of the MAC header, and is known from the length of the LF. Thereafter, the receiver compares the size of the MAC PDU with the known TB size.
If the size of the MAC PDU is the same as the TB size, the receiver determines in step 625 that the MAC PDU includes the last LF, and in step 627 extracts the MAC SDU from the MAC PDU using the LF. In step 629, the receiver processes the MAC SDU extracted by its LCID.
On the other hand, if it is determined in step 623 that the size of the MAC PDU is different from the TB size, the receiver determines in step 631 that the MAC PDU does not include the last LF. The reason why the two values are different is that the last LF is omitted and the last LF is included and the LF is confirmed. In step 627, the receiver extracts the MAC SDU using the LF, and calculates the MAC SDU length based on the existing LF value and the TB size, thereby obtaining the MAC SDU corresponding to the omitted LF. Extract. The receiver then processes the MAC SDU with each LCID at step 629. If the last LF is not included, it is determined that the remaining payload of the MAC PDU after the previously extracted MAC SDU belongs to the last MAC SDU.

Corresponding to FIG. 5E showing the second embodiment of PDU generation, referring to FIG. 6E showing the second embodiment of SDU parsing, the receiver sets the E field for the MAC SDU to '1' in step 641. It is determined whether or not it is set. If the E field is '1', the receiver determines that there are more MAC SDUs multiplexed in the received MAC PDU, and is shown in FIG. 6A, FIG. 6B, and FIG. Proceeding to one procedure, the operation is repeated until the subheaders of all the MAC SDUs defined in the MAC header are confirmed.
If the E field is set to '0' which means that there are no more MAC SDUs multiplexed after the MAC SDU, the receiver will determine whether the MAC header contains the last LF. Then, the process proceeds to step 643.
In step 643, the receiver determines whether the R field (or other indicator) has been set. As described above, if the required padding size exceeds the length of the last LF, the R field means "MAC PDU does not contain the last LF but padding does". Thus, once the R field is set, the receiver determines the padding size via the value of the R field at step 649.
In step 645, the receiver extracts the MAC SDU from the MAC PDU considering the LF value, padding size, and TB size, and in step 647, processes the MAC SDU with each LCID.
Alternatively, if it is determined that the R field is not set, that is, for example, if the R field is an initial value of all “0”, the receiver sets the value of LF in step 645 without passing through step 649. In consideration, the MAC SDU is extracted from the MAC PDU.

Referring to FIG. 6F showing the third embodiment of SDU parsing corresponding to case 3 of FIG. 5D according to the first embodiment of PDU generation, the receiver sets the E field for MAC SDU to '1'. In step 651, it is determined that LF exists for the MAC SDU, and in step 652, the size of the MAC SDU is calculated using the LF. If there is a previously accumulated MAC PDU size, the receiver updates this accumulated size by adding the calculated MAC SDU size and the MAC header size to the pre-accumulated size.
In step 653, the receiver compares the updated cumulative size with a known TB size. If it is determined that this cumulative size is the same as the TB size, the receiver determines in step 654 that the last LF is included in the MAC PDU, and in step 656, the MAC PDU is used to determine the MAC PDU from the MAC PDU. Extract the SDU. In step 657, the receiver processes the MAC SDU extracted by its LCID. On the other hand, if it is determined that the accumulated size is different from the TB size, the receiver returns to the procedure shown in one of FIGS. 6A, 6B, and 6C, as indicated by reference symbol B.
If it is determined in step 651 that the E field for the MAC SDU is '0', the receiver determines in step 655 that the LF is not included for the MAC SDU and the previously confirmed MAC SDU. , It is determined that the remaining MAC PDU belongs to the last MAC SDU, and in step 656, the MAC PDU is extracted from the MAC PDU using the LF. In step 657, the receiver processes the MAC SDU extracted by its LCID. When reception of the MAC PDU is completed, the accumulated size is reset to update the accumulated size for the next MAC PDU.

Referring to FIG. 6G, which shows a fourth embodiment of SDU parsing corresponding to case 4 of FIG. 5D according to the first embodiment of PDU generation, the receiver sets the E field for MAC SDU to '0'. Then, it is determined that the MAC SDU corresponding to the E field is the last MAC PDU, and in step 663, it is confirmed whether or not the LF following the E field is set to a predetermined pattern. When the LF has a predetermined pattern, the receiver determines that the padding size required for generating the MAC PDU is less than or equal to the length of the last LF, and the transmitter transmits the last LF set to a predetermined value. judge. In one embodiment, if the last LF is 7 bits, the predetermined pattern may be '0000 000'.
The receiver determines that the last LF is included in the MAC PDU in step 665, extracts the MAC SDU from the MAC PDU using the LF of the MAC SDU in step 667, and processes the MAC SDU by the LCID in step 669 ( (Reception Operation for Case 4 in FIG. 5D).
On the other hand, if the LF value is different from the predetermined pattern, the receiver determines in step 671 that the last LF is not included in the MAC PDU, and in step 667 uses the MAC SDU LF to obtain the MAC SDU from the MAC PDU. Extract and process the MAC SDU extracted by LCID in step 669. At this time, it is determined that the last MAC SDU occupies the remaining portion after the MAC SDU previously extracted in the payload of the MAC PDU.
If it is determined in step 661 that the E field for the MAC SDU is '1', the receiver may perform the procedure shown in FIG. 6A, FIG. 6B, and FIG. Return to and repeat until the MAC header confirms the subheaders for all MAC SDUs.

Referring to FIG. 6H illustrating a fifth embodiment of SDU parsing corresponding to case 5 of FIG. 5D according to the first embodiment of PDU generation, the receiver sets the E field for MAC SDU to '1'. In step 681, it is determined that LF exists for the MAC SDU, and in step 683, the LF pattern is confirmed. If the LF is the same as the predetermined pattern, the receiver determines that the padding size required for generating the MAC PDU is less than or equal to the length of the last LF, the transmitter sets the E field to '1', and the MAC It is determined that the LF of the MAC SDU is set to a predetermined pattern in order to indicate the presence of the LF for the SDU.
Therefore, the receiver determines that the last LF is included in the MAC PDU at step 685, extracts the MAC SDU from the MAC PDU using the LF of the MAC SDU at step 687, and processes the MAC SDU with the LCID at step 689. (Reception operation for case 5 in FIG. 5D).
On the other hand, if it is determined that the LF pattern is different from the predetermined pattern, the receiver confirms the LF to be used for MAC SDU extraction in step 687, and represents the reference LF as shown in FIG. 6A, FIG. Returning to the procedure shown in one of FIGS. 6C, the operation is repeated until the MAC header confirms the subheaders of all MAC SDUs.
If the E field for the MAC SDU is '0' in step 681, the receiver determines in step 691 that no LF is included for the MAC SDU and uses the LF of the MAC SDU in step 687. The MAC SDU is extracted from the MAC PDU, and the MAC SDU extracted by the LCID is processed in Step 689. If the last LF is not included, the last MAC SDU is determined to occupy the remaining portion of the MAC PDU excluding the MAC SDU previously extracted in the MAC PDU payload.

<Second Embodiment>
FIG. 7 shows a format of a MAC PDU according to the second embodiment of the present invention.
Referring to FIG. 7, a MAC PDU includes a plurality of MAC subheaders 705 and 710 and a plurality of payloads 715 and 720 carrying a plurality of MAC SDUs or a plurality of MAC control information.
Each MAC subheader 705 or 710 provides multiplexing information for MAC PDU or MAC control information 715 or 720. The MAC PDU has the number of payloads equal to the number of MAC subheaders. The mapping relationship between the MAC subheaders 705 and 710 and the payloads 715 and 720 is based on the order of the payloads 715 and 720. For example, the first and second MAC subheaders 705 and 710 represent the first and second payloads 715 and 720, respectively.
Each MAC subheader includes LCID 725, E730, flag F745, length (ie, LF) 750, and R735, 740. The LCID 725 provides the ID of the logical channel that carries the corresponding MAC SDU or indicates the type of the corresponding MAC control information. E730 indicates whether or not the MAC subheader is the last subheader, and LF745 indicates the length of the MAC SDU or MAC control information. In order to reduce the processing load on the transmitter and receiver, the MAC subheaders 705, 710 are byte-aligned, and for this purpose the 2-bit R fields 735, 740 are used. The LF 750 is 7 or 15 bits, and the preceding F field 745 indicates the length of the LF 750. For example, if the F field 745 is set to 0, the LF 750 is 7 bits, and if the F field 745 is set to 1, the LF 750 is 15 bits. When the LF 750 is 7 bits, the LF 750 can be displayed with a maximum length of 127 bytes. When the LF 750 is 15 bits, the LF 750 can be displayed with a maximum length of 32768 bytes.

As shown in FIG. 7, the length of the MAC subheader is 1, 2 or 3 bytes. Since the LF and F fields are not included in the last MAC subheader, the length of the last MAC subheader is usually 1 byte. As described above, it is desirable to include the last LF when the absence of LF in the last MAC subheader triggers padding of 1 or 2 bytes.
Padding of 1 or 2 bytes occurs when the required padding size is less than or equal to the sum of the lengths of LF and F. Padding of 1 or 2 bytes occurs when the required padding size is greater than or equal to the sum of the lengths of LF and F It can be said that it occurs in some cases as a general theory. For the sake of completeness, instead of determining whether the required padding size is greater than the sum of the lengths of LF and F, determine whether the required padding size is 1 or 2 bytes. To do.
Therefore, in the second embodiment of the present invention, the length of the last LF is determined depending on whether the padding size is 1 byte or 2 bytes in the removal of the last LF. The LF of the last MAC subheader is set to a value indicating that the corresponding MAC SDU is the last MAC SDU. The reason is that although 2 bytes are available for the last MAC subheader, the length of the last MAC SDU may exceed the maximum value representing the LF of the 1-byte MAC subheader.
For example, when a 1000-byte MAC PDU transfers a 196-byte first MAC SDU and an 800-byte second MAC SDU, the first MAC subheader is 2 bytes, and the LF is calculated from the second MAC subheader. When removed, that is, the last MAC subheader has a total MAC PDU size of 999 bytes, and therefore 1-byte padding is required. If LF is included in the last MAC subheader, only 7 bits can be used in the last LF, but 15 bits are required to express the length of 800 bits.
In order to solve the above problems, the transmitter and receiver pre-promise the LF value representing the last MAC subheader. If the absence of F and LF in the last MAC subheader causes 1 or 2 bytes of padding, an LF having a size corresponding to the expected padding size is inserted into the last MAC subheader and this LF is set to the above value. By doing so, the receiver can correctly demultiplex the MAC SDU.

FIG. 8 is a flowchart illustrating a transmission operation according to the embodiment of the present invention.
Referring to FIG. 8, in step 805, the transmitter senses the occurrence of a MAC PDU generation event. For example, when a transmitter of a mobile terminal (MS) receives information on a reverse transmission resource and a MAC PDU size from a base station (BS) scheduler, it recognizes that a MAC PDU of the MAC PDU size is generated. In step 810, the transmitter determines a logical channel for transmitting data by referring to the size of the MAC PDU and the amount of data buffered in the upper layer buffer, and determines the size of the MAC SDU for each logical channel. . The transmitter generates a remaining MAC subheader excluding the last MAC subheader for each MAC SDU by a general method.

Then, if it is determined in step 815 that the transmitter generates the last MAC subheader, then in step 820 whether the absence of F and LF in the last MAC subheader causes 1 or 2 bytes of padding. judge. As a result, if 1 or 2 bytes of padding occur, the transmitter proceeds to step 835, otherwise proceeds to step 825. In step 825, the transmitter determines that padding does not occur even if F and LF of the last MAC subheader are removed, and thus sets the E field of the last MAC subheader to '0'. The transmitter then completes generation of this last MAC subheader at step 830 by removing the F and LF of the last MAC subheader. The value of this E field has the following meaning.
1: F and LF exist in the MAC subheader. When the LF is set to a predetermined value, for example, “0000 000” or “0000 0000 0000 000”, the MAC subheader is the last MAC subheader, and the MAC control information or MAC SDU follows the MAC subheader. If LF is not a predetermined value, the MAC subheader is followed by another MAC subheader.
0: The MAC subheader is the last MAC subheader and does not include F and LF. This MAC subheader is followed by MAC control information or MAC SDU.

The transmitter determines that the last F and LF are included because removal of the last F and LF generates 1 or 2 bytes of padding. Therefore, the transmitter sets the E field to '1' indicating inclusion of F and LF in the last MAC subheader in step 835, and removal of the last F and LF generates 1 byte of padding in step 840. Or whether to generate 2-byte padding. The transmitter proceeds to step 845 if it is 1-byte padding and proceeds to step 855 if it is 2-byte padding.
In step 845, the transmitter sets F to '0' indicating that the length of LF is 7 bits. Thereafter, in step 850, the transmitter sets LF to a predetermined value, eg, '0000 000'. In step 855, the transmitter sets F to '1' indicating that the length of the LF is 15 bits, and in step 860 sets LF to a predetermined value, for example, '0000 0000 0000 000'. The predetermined value “0000 000” or “0000 0000 0000 000” indicates that the MAC subheader is the last MAC subheader, and that this MAC subheader is followed by MAC SDU or MAC control information.
When the setting for all the fields of the MAC subheader is completed, the transmitter generates a MAC PDU in which the MAC subheader and the MAC SDU are concatenated and transmits them to the receiver through the lower layer in step 865.
In the present invention, since the transmitter according to the second embodiment can be easily realized from the transmitter according to the first embodiment described above, detailed description thereof is omitted.

FIG. 9 is a flowchart illustrating a reception operation according to the embodiment of the present invention.
Referring to FIG. 9, the receiver receives the MAC PDU through the lower layer in step 905, and decodes and analyzes the MAC subheader of the MAC PDU in step 910. This MAC subheader is analyzed in the order of transfer to the MAC PDU. For each MAC subheader, the receiver determines in step 915 whether the E field of the MAC subheader is '0'. Here, '0' means that the MAC SDU represented by the MAC header is the last MAC SDU, and this MAC subheader does not include F and LF. If the E field is '0', in step 925, the receiver subtracts the MAC SDU by subtracting the sum of the lengths of other MAC subheaders and other MAC SDUs or MAC control information from the overall size of the MAC PDU. Determine the size of the. In step 930, the receiver demultiplexes the MAC PDU according to the LCID of the MAC subheader and the calculated size of the MAC SDU to extract the MAC SDU from the MAC PDU.
If it is determined that the E field is '1', the receiver determines in step 920 whether the LF of the MAC subheader is a predetermined value, for example, '0000 000' or '0000 0000 0000 000'. . Here, '1' indicates that the MAC subheader includes F and LF, and the value of LF indicates whether the next byte of the MAC subheader belongs to another MAC subheader or belongs to the MAC SDU / MAC control information. means. If the LF is a predetermined value in which the MAC subheader is the last MAC subheader, whereby the length of the last MAC SDU has to be calculated, the receiver calculates the length of the last MAC SDU in step 925 In step 930, the last MAC SDU is extracted from the MAC PDU according to the length of the last MAC SDU. Thereafter, the receiver ends the process for the MAC PDU.
If LF is not a predetermined value, the MAC subheader is not the last MAC subheader, and LF represents the length of the corresponding MAC SDU. Accordingly, the receiver extracts the MAC SDU from the MAC PDU using the LCID, F, and LF of the MAC subheader at step 935 and returns to step 910 to process the next MAC subheader.
In the present invention, the receiver according to the second embodiment can be easily realized from the receiver according to the first embodiment described above, and thus detailed description thereof is omitted.

  While the invention has been illustrated and described with reference to specific embodiments, various changes in form and detail can be made without departing from the spirit and scope of the invention as defined by the appended claims. Certainly it will be apparent to those with ordinary knowledge in the art.

300 Multiplexer (MUX)
302, 304, 306 RLC entity 308 MAC controller 310 Header generator 400 Header detector 402 SDU detector 404 RLC entity 406 MAC controller

Claims (42)

A method for generating a media access control protocol data unit (MAC PDU) in a mobile communication system, comprising:
Confirming the logical channel identifier (LCID) of the media access control service data unit (MAC SDU) to be multiplexed;
Determining a length of the LF for each MAC SDU with reference to a length of a predetermined length field (LF) for the LCID;
Generating a MAC header including an LCID for the MAC SDU and a length of the determined LF;
Generating a MAC PDU by combining the MAC header with a payload including the MAC SDU; and
The step of generating the MAC header includes:
Assuming that the last LF of the MAC header is omitted, if the padding size necessary for generating the MAC PDU is larger than the length of the last LF, the last LF is included in the MAC header and the last LF is included. Recalculating the required padding size taking into account the inclusion of LF, and adding padding according to the recalculated padding size. The step of generating the MAC header includes:
The method of claim 1, further comprising: including the last LF in the MAC header if the required padding size is less than or equal to the length of the last LF. The step of generating the MAC header includes:
If the required padding size is less than or equal to the length of the last LF, the last LF is included in the MAC header, and a predetermined reserved bit of the MAC header is set to a value indicating inclusion of the last LF. The method of claim 1, further comprising a step. The step of generating the MAC header includes:
If the required padding size is less than or equal to the length of the last LF, include the last LF in the MAC header and include an E field associated with the last MAC SDU of the MAC PDU to include the last LF. The method of claim 1, further comprising the step of setting to the indicated value. The step of generating the MAC header includes:
If the required padding size is less than or equal to the length of the last LF, the last LF is included in the MAC header, and the last LF is set to a predetermined pattern indicating inclusion of the last LF. The method of claim 1, further comprising: The step of generating the MAC header includes:
If the required padding size is less than or equal to the length of the last LF, include the last LF in the MAC header and include an E field associated with the last MAC SDU of the MAC PDU to include the last LF. The method according to claim 1, further comprising the step of: setting a value to be indicated and setting the last LF to a predetermined pattern indicating inclusion of the last LF. The step of generating the MAC header includes:
If the required padding size is less than or equal to the length of the last LF, the last LF is excluded from the MAC header and indicators indicating the absence of the last LF and the presence of padding are included in the MAC header. The method of claim 1, further comprising setting the padding size to a value.   The method of claim 1, wherein the length of the LF predetermined for the LCID comprises a minimum value required to represent a size of a transfer block (TB). An apparatus for generating a media access control protocol data unit (MAC PDU) in a mobile communication system,
A multiplexing media access control service data unit (MAC SDU) is provided to the multiplexer, a logical channel identifier (LCID) of the MAC SDU is confirmed, and a length of a long field (LF) for each of the MAC SDUs is determined. At least one radio link control (RLC) entity that refers to a predetermined LF length for the LCID and provides the LCID and the determined LF length to a header generator;
The header generation unit for generating a MAC header including an LCID for the MAC SDU and a length of the determined LF and providing the MAC header to the multiplexer;
The multiplexer for multiplexing the MAC header with the at least one MAC SDU;
When the padding size required for the MAC PDU is larger than the length of the last LF in a state where the last LF of the MAC header is absent, the header generator adds the last LF to the MAC header. In addition, the necessary padding size is recalculated in consideration of inclusion of the last LF, padding is added according to the recalculated padding size, and the last LF is included in the MAC header. apparatus. The header generator
The apparatus of claim 9, wherein the last LF is included in the MAC header if the required padding size is less than or equal to the length of the last LF. The header generator
If the required padding size is less than or equal to the length of the last LF, the last LF is included in the MAC header, and a predetermined reserved bit of the MAC header is set to a value indicating inclusion of the last LF. The apparatus according to claim 9. The header generator
If the required padding size is less than or equal to the length of the last LF, include the last LF in the MAC header and include an E field associated with the last MAC SDU of the MAC PDU to include the last LF. The apparatus according to claim 9, wherein the apparatus is set to a value indicated. The header generator
If the required padding size is less than or equal to the length of the last LF, the last LF is included in the MAC header, and the last LF is set to a predetermined pattern indicating inclusion of the last LF. The apparatus of claim 9. The header generator
If the required padding size is less than or equal to the length of the last LF, include the last LF in the MAC header and include an E field associated with the last MAC SDU of the MAC PDU to include the last LF. The apparatus according to claim 9, wherein the device is set to a value to indicate, and the last LF is set to a predetermined pattern indicating inclusion of the last LF. The header generator
If the required padding size is less than or equal to the length of the last LF, the last LF is excluded from the MAC header and indicators indicating the absence of the last LF and the presence of padding are included in the MAC header. The apparatus according to claim 9, wherein the apparatus is set to a value indicating a padding size.   The apparatus according to claim 9, wherein the length of the LF predetermined for the LCID comprises a minimum value required to represent a size of a transfer block (TB). A method for parsing a media access control service data unit (MAC SDU) from a media access control protocol data unit (MAC PDU) in a mobile communication system, comprising:
Confirming the logical channel identifier (LCID) of the MAC SDU multiplexed in the MAC PDU received from the MAC header of the MAC PDU;
Determining whether the length of the MAC PDU calculated using the MAC header is the same as the size of a known transport block (TB);
Determining that a last long field (LF) associated with the last MAC SDU is included in the MAC header, and parsing the MAC SDU from the MAC PDU by the LF in the MAC header;
If the length of the MAC PDU is not the same as the TB size, it is determined that the last LF is not included in the MAC header, and the MAC PDU is transmitted from the MAC PDU by the absent last LF and the LF in the MAC header. Parsing the
A method comprising the steps of: Parsing the MAC SDU by the LF of the MAC header comprises:
18. The method according to claim 17, wherein if the predetermined reserved bit of the MAC header is set to a value indicating inclusion of the last LF, it is determined that the last LF is included in the MAC header. the method of. Parsing the MAC SDU by the LF of the MAC header comprises:
When the E field associated with the first MAC SDU is set to a value indicating inclusion of the LF associated with the first MAC SDU in the MAC header, the LF associated with the first MAC SDU is Determining that it is included in the MAC header;
Calculating a cumulative length of the MAC PDU taking into account the LF associated with the first MAC SDU;
If the accumulated MAC PDU size is the same as the TB size, determining that the last LF is included in the MAC header;
18. The method of claim 17, comprising: Parsing the MAC SDU with the LF in the MAC header and the last LF absent
If the E field associated with the second MAC SDU is not set in the MAC header to a value indicating inclusion of the LF associated with the second MAC SDU, the E field associated with the second MAC SDU is the LF associated with the second MAC SDU. 20. The method of claim 19, wherein it is determined that a last LF is not included in the MAC header. Parsing the MAC SDU with the LF in the MAC header comprises:
When data having an LF length adjacent to an E field set to a value indicating the last MAC SDU is set in a predetermined pattern, it is determined that the last LF is included in the MAC header. The method according to claim 17. Parsing the MAC SDU with the LF in the MAC header and the last LF absent
If the LF length data adjacent to the E field set to a value indicating the last MAC SDU is not set in a predetermined pattern, it is determined that the last LF is not included in the MAC header. The method according to claim 21, wherein: Parsing the MAC SDU with the LF in the MAC header comprises:
When the E field associated with the first MAC SDU is set to a value indicating inclusion of the LF associated with the first MAC SDU, and the LF associated with the first MAC SDU is set to a predetermined pattern 18. The method of claim 17, wherein a first MAC SDU is the last MAC SDU and the LF associated with the first MAC SDU is included in the MAC header. Parsing the MAC SDU with the LF in the MAC header and the last LF absent
If the E field associated with the second MAC SDU is not set to a value indicating inclusion of the LF associated with the second MAC SDU that is the last LF, the LF associated with the second MAC SDU is The method of claim 23, wherein the method is determined not to be included in the MAC header. Parsing the MAC SDU with the LF in the MAC header comprises:
When set to a value indicating the size of padding in which an indicator is added due to the absence of the last LF in the MAC header, the size of the padding added by the indicator is confirmed, and the padding size is taken into account The method of claim 17, wherein parsing the MAC SDU. An apparatus for parsing a media access control service data unit (MAC SDU) with a media access control protocol data unit (MAC PDU) in a mobile communication system,
The logical channel identifier (LCID) of the MAC SDU multiplexed on the MAC PDU is confirmed from the MAC header of the received MAC PDU, and the length of the long field (LF) predetermined for the LCID is used. A header detector that provides a size of the multiplexed MAC SDU to the SDU detector;
If the MAC PDU length calculated using the LCID and the MAC SDU size is the same as a known transport block (TB) size, the SDU detector determines the last LF associated with the last MAC SDU. If the MAC header is determined to be included in the MAC header, the MAC SDU is parsed from the MAC PDU by the LF of the MAC header, and the length of the MAC PDU is not the same as the TB size, the last LF is included in the MAC header. Determining that the MAC SDU is not present and parsing the MAC SDU from the MAC PDU with the last LF absent and the LF in the MAC header.   When parsing the MAC SDU with the LF of the MAC header, the SDU detector is configured such that when a predetermined reserved bit of the MAC header is set to a value indicating inclusion of the last LF, 27. The apparatus of claim 26, wherein the apparatus determines that the last LF is included in a header.   When parsing the MAC SDU with the LF in the MAC header, the SDU detector includes an E field associated with the first MAC SDU in the MAC header including the LF associated with the first MAC SDU. When set to the value indicated, it is determined that the LF associated with the first MAC SDU is included in the MAC header, and the MAC PDU is considered in consideration of the LF associated with the first MAC SDU. 27. The accumulated length of the first LF is calculated, and if the accumulated MAC PDU size is the same as the TB size, it is determined that the last LF is included in the MAC header. The device described.   When parsing the MAC SDU with the LF in the MAC header and the last LF absent, the SDU detector has an E field associated with a second MAC SDU in the second MAC SDU in the MAC header. If it is not set to a value indicating inclusion of the related LF, it is determined that the last LF, which is an LF related to the second MAC SDU, is not included in the MAC header. Item 29. The apparatus according to Item 28.   When parsing the MAC SDU by the LF in the MAC header, the SDU detector sets the LF length data adjacent to the E field set to a value indicating the last MAC SDU in a predetermined pattern. 27. The apparatus of claim 26, wherein the apparatus determines that the last long field exists.   When parsing the MAC SDU by the MAC header and the absent last LF, the SDU detector is configured to receive the LF length data adjacent to the E field set to a value indicating the last MAC SDU. 31. The apparatus according to claim 30, wherein, if is not set to a predetermined pattern, it is determined that the last LF is not included in the MAC header.   When parsing the MAC SDU by the LF of the MAC header, the SDU detector sets the E field associated with the first MAC SDU to a value indicating inclusion of the LF associated with the first MAC SDU. If set and the LF associated with the first MAC SDU is configured in a predetermined pattern, the first MAC SDU is the last MAC SDU and the LF associated with the first MAC SDU 27. The apparatus of claim 26, wherein the device is determined to be included in the MAC header.   When parsing the MAC SDU with the MAC header and the absent last LF, the SDU detector may provide the second MAC SDU with the E field associated with the second MAC SDU being the last LF. 33. The apparatus of claim 32, wherein if not set to a value indicating inclusion of an associated LF, the apparatus determines that the LF associated with the second MAC SDU is not included in the MAC header. .   When parsing the MAC SDU with the LF of the MAC header, the SDU detector is set to a value indicating a padding size to which an indicator is added due to the absence of the last LF of the MAC header. 27. The apparatus of claim 26, wherein the MAC SDU is parsed by checking a size of padding added by the indicator in consideration of the above. A method for generating a media access control protocol data unit (MAC PDU) in a mobile communication system, comprising:
Confirming the logical channel identifier (LCID) of the media access control service data unit (MAC SDU) to be multiplexed;
Determining a length of the LF for each MAC SDU with reference to a length of a predetermined length field (LF) for the LCID;
Generating a MAC header including an LCID for the MAC SDU and the LF of the determined length;
Adding a MAC header to a payload containing the MAC SDU to generate a MAC PDU;
The step of generating the MAC header includes calculating a padding size required for generating the MAC PDU calculated assuming a last LF of the MAC header and a absence of a length indicator for the last LF. Greater than the sum of the length indicators and the length indicator, the MAC header does not include the last LF and the length indicator, and the E field included in the MAC header is replaced by the last length field and the length identifier. Set to a value indicating that is absent.   The step of generating the MAC header includes including the last LF and the length indicator in the MAC header when the required padding size is less than or equal to the sum of the length of the last LF and the length indicator. Further comprising setting an E field to a value indicating that the last LF and the length indicator are included, and setting a subheader including the last LF to a predetermined value indicating that the last subheader is the last subheader. 36. The method of claim 35. An apparatus for generating a media access control protocol data unit (MAC PDU) in a mobile communication system,
A multiplexing media access control service data unit (MAC SDU) is provided to the multiplexer, a logical channel identifier (LCID) of the MAC SDU is confirmed, and a length of a long field (LF) for each MAC SDU is determined. At least one radio link control (RLC) entity that refers to a predetermined LF length for the LCID and provides the LCID and the determined LF length to a header generator;
Generating a MAC header including an LCID for the MAC SDU and an LF of the determined length and providing the MAC header to the multiplexer; and
The multiplexer for multiplexing the MAC header with at least one of the MAC SDUs;
The header generation unit calculates a padding size required for generating the MAC PDU calculated assuming the last LF of the MAC header and the absence of a length indicator for the last LF, and the length indicator. Is greater than the sum of the lengths, the last LF and the length indicator are not included in the MAC header, and the E field is set to a value indicating the absence of the last LF and the length indicator in the MAC header. A device characterized by that. The header generator
If the required padding size is less than or equal to the sum of the length of the last LF and the length indicator, the last LF and the length indicator are included in the MAC header and the E field is the last LF. The apparatus according to claim 37, wherein the apparatus is set to a value indicating inclusion of the length indicator, and is set to a predetermined value indicating that the subheader including the last LF is the last subheader. A method of parsing a media access control service data unit (MAC SDU) with a media access control protocol data unit (MAC PDU) in a mobile communication system, comprising:
Confirming the logical channel identifier (LCID) of the MAC SDU multiplexed in the MAC PDU from the MAC header of the received MAC PDU, and confirming the E field of the MAC header;
If the E field is set to a last length field (LF) associated with the last MAC SDU and a predetermined value indicating the absence of the length indicator for the last LF, the missing last LF and length Calculating the length of the last MAC SDU taking into account an indicator;
Parsing the MAC SDU from the MAC PDU using the LCID and the length of the last MAC SDU;
A method comprising the steps of: The step of calculating the length of the last MAC SDU is:
The E field is set to a predetermined value indicating inclusion of the last LF and the length indicator for the last MAC SDU, and a predetermined value indicating that the MAC SDU associated with the last LF is the last MAC SDU 40. The length of the last MAC SDU is calculated taking into account that the MAC SDU associated with the last LF is the last MAC SDU when set to a value. The method described. An apparatus for parsing a media access control service data unit (MAC SDU) with a media access control protocol data unit (MAC PDU) in a mobile communication system,
A header detector for confirming a logical channel identifier (LCID) of a MAC SDU multiplexed in the MAC PDU from a MAC header of the received MAC PDU, and confirming an E field of the MAC header;
If the E field is set to a predetermined value indicating the absence of a length field (LF) associated with the last MAC SDU and the length indicator for the last LF, the missing last LF and the length indicator are considered. Calculating a length of the last MAC SDU and parsing the MAC SDU from the MAC PDU using the LCID and the length of the last MAC SDU;
The apparatus characterized by including. The SDU detector is
The E field is set to a predetermined value indicating inclusion of the last LF and the length indicator for the last MAC SDU, and the last LF is associated with the last LF. When set to a predetermined value indicating an SDU, the length of the last MAC SDU is calculated considering that the MAC SDU associated with the last LF is the last MAC SDU. 42. Apparatus according to claim 41, characterized in that

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